WO2010149209A1 - Injection device having a dosing mechanism for limiting a dose setting - Google Patents

Abstract

The invention relates to an injection device comprising: a) a dose setting element (9; 10; 7; 4) and a first element (13) coupled thereto, which first element can be rotated relative to another second element (2; 5; 100) during a dose setting and is rotationally fixed relative to the second element (2; 5; 100) during a dose discharge, wherein the first element (13) and the second element (2; 5; 100) are coupled by means of a coupling element (30), and b) a stop (7b; 100a), wherein the coupling element (30) moves to a stop position during a dose setting, wherein the coupling element (30) in the stop position prevents the setting of a dose.

Description

 Injection device with a metering mechanism for limiting a

dose adjustment

The invention relates to an injection processing mechanism which prevents the setting of a dose exceeding the amount of a product to be administered in a product container of the injection device. The product to be administered may be e.g. to be a liquid drug, especially to act on insulin.

From the prior art, a metering mechanism for an injection device for preventing the setting of a dose is known, which exceeds the amount of medication in a reservoir of an injection device. Such devices often have the problem of consuming a relatively large amount of space in the injection device. On the other hand, the market demands handy injection devices.

With injection devices known from the prior art, doses can be adjusted with a dose setting mechanism and subsequently dispensed from a product container. It may be the case that a larger dose has been set with the dose setting element than can be released from the product container, e.g. because the product container contains a lower dose than the dose that was discontinued. This may result in less product being released than has been set, which, depending on the deviation, may cause more or less major problems for the patient.

It is therefore an object of the invention to provide a compact built-in mechanism for preventing the setting of a dose exceeding the amount of a product contained in the product container of the injection device. The object is achieved with an injection device having the features of claim 1. Advantageous further developments emerge from the dependent claims and the description.

The invention is based on an injection device comprising a Doseinstellelement and first element coupled thereto, which is rotatable relative to another, second element at a dose setting and rotationally fixed at a dose distribution relative to the second element, wherein the first element and the second element via a Coupling link, which can also be referred to as a stop member are coupled. The dose setting element is preferably rotatable and may be axially fixed or longitudinally movable relative to the housing. For example, in the rotational movement, the dose setting element may undergo longitudinal movement, such as, e.g. perform a screwing. For example, the dose setting member may be rotated by the user of the dose setting device relative to the housing in at least one direction, preferably first metering and dosing, which may be referred to as dose correction, in a second direction of rotation opposite to the first rotational direction become. The dosage setting element may be sleeve-shaped and may be e.g. in the region of the proximal end of the injection device. Alternatively or additionally, the dose setting element can be arranged inside the housing of the device, wherein the housing and dose setting element can be sleeve-shaped. It is conceivable that the user does not have immediate access to the dose setting element, but rather to additional parts. Basically, the dose setting element may be a multi-part of e.g. be formed rotationally or translationally to each other moving parts, wherein a one-piece Doseinstellelement is conceivable. The dose setting element located inside the housing may e.g. a dose indicator sleeve, e.g. can be read through an opening or window from the outside.

The first rotatable element and / or the second rotatable element are preferably sleeve-shaped and / or can rotate about a common axis, this axis pointing, for example, in the longitudinal direction of the injection device or in the direction of the needle. The first element and the second element may be arranged concentrically with each other, wherein preferably the first element surrounds the second element or a passage for the second Element forms. An annular gap can be arranged between the first element and the second element, in which, for example, the coupling element can be arranged.

The dose setting element may be indirectly or directly coupled to the first element. Preferably, the dose setting element is connected to the first element when setting the

Dose rotatably coupled. This coupling can be achieved, for example, in the distribution of the adjusted product dose, in particular via a coupling. Alternatively, the

Dose setting permanently be rotatably coupled to the first element, in particular when the dose setting is a dose display sleeve, in which case the dose display sleeve can be axially displaceable relative to the first element.

Characterized in that the first element is rotatable relative to the second element at a dose setting, the coupling member relative to the first element and / or to the second element perform a relative movement. Characterized in that the first element is rotationally fixed in the dose distribution relative to the second member, a movement of the coupling member relative to the first member and the second member can be prevented. For example, the first element, the second element and the coupling member in the dose distribution together, in particular rotate relative to the housing. Preferably, a clutch is provided, which is in the dose setting in a first coupling state and in the dose distribution in a second coupling state. The coupling may be connected to the first and the second element such that in the first, z, B. in the opened coupling state, the first element can rotate relative to the second element, wherein the first element in the second coupling state, in particular in the closed coupling state, is rotationally fixed relative to the second element. Depending on whether the user wants to set or distribute a dose, he can operate the clutch to establish the desired coupling state.

The coupling member may preferably engage positively in the first element and the second element. The first element and the second element may each have a guideway in which engages the coupling member. The guide tracks may be designed or thread-shaped wendelfb ^'RMIG or as a longitudinal guide which extends parallel to the longitudinal direction of the injection device or to the rotation axis of the first or second member in approximately. Preferably, at least one of the guideways is threaded or helical. The pitches for the threads of the first element and the second element may be of different sizes and / or opposed, wherein in the latter, the threads or coils have an opposite direction of rotation. Preferably, the guideways of the first element and the second element are opposite. The guideway of the first element can eg be formed on the inner circumference of the first element, for example as a thread or internal thread, and the guideway of the second element can be formed, for example, on the outer circumference of the second element as a thread or external thread. In particular, in the guideways of the first element and the second element should not interlock, ie be free of mesh. Only the coupling member, wherein a plurality of coupling members can be provided, couples the guide track of the first element with the guide track of the second element.

In preferred embodiments, the coupling member may be a ball, a ring, a nut, in particular a stop nut, or a segment. A ball has the particular advantage that it does not need to have a specially equipped for engagement in the guideways engaging member, but coupled by their rotationally symmetrical shape in all its possible positions, the first and the second element. The ball does not need to be specially aligned. The guideways can be adapted with their cross-sectional shape to the contour of the ball. In particular, at least one of

Guideways, preferably both, be concave and / or rounded in cross-section and / or approximately circular.

A ring or nut having an annular cross-section forms a passageway for the second member, and advantageously supports the second member in all directions transverse to the longitudinal axis toward the first member. At the nut are for each of the guideways. their outer and inner circumference corresponding engagement elements, such. Threaded sections, formed for engagement in the respective guideway.

A segment-shaped coupling member, which may in particular be a segment of the stop nut, has the advantage that the annulus is not completely filled, thereby material on the one hand and space on the other hand is saved. Under certain conditions, a segment can be particularly easy to install.

The coupling member may be formed in several parts in other embodiments, such. be formed by two axially fixed and relative to each other rotatably connected parts, one of which is designed so that it engages in the guideways and the other, for example, has a stop, which, for example. engages with a stop stop described later to prevent further dose adjustment. The parts forming the coupling member may, for example, be rotated relative to each other by a certain angle, which is preferably less than 360 ° and more preferably less than 180 °. The two interlocking parts can generate in their movement to each other by means of a latching element at least one, preferably a plurality, audible or tactile click that indicates the user of the device reaching the stop position. The click may be generated upon reaching the stop position or before reaching the stop position and, in particular, sound different or feel different than other clicks generated by the device. Preferably, the click is generated by further rotation of the dose setting element by the angle by which the two parts of the coupling member are rotatable relative to each other. The achievement of this stop position is thus announced advantageous. In particular, the two parts of the coupling member may be biased against each other with a spring. This can ensure that the two parts are rotated by the specific angle to each other, with this angle is reduced and the two parts against the spring force rotate relative to each other when the coupling member is in a stop with a stop stop.

The injection device further comprises a stop stop, wherein at a dose setting, the coupling member performs a movement to the stop position, in particular to the stop stop, the coupling member in the stop position, in particular stops at the stop stop the setting of a dose. In particular, the increase in the dose can be prevented, wherein advantageously the dose correction, ie dose reduction is possible, for example because the coupling member is moved away from the stop stop. In particular, the coupling member during the dose distribution no movement out to the stop position or away from the stop position. Of the Stop stop may be formed by at least one first element, in particular a rotatably or axially fixed to the first element element, and the second element, in particular an axially or rotationally fixedly connected to the second element element. For example, the end of the guideway or guideways may each form a stop stop.

In principle, the stop stop can act in the axial direction, wherein it is preferred that the stop stop acts in the direction of rotation. A stop acting in the direction of rotation directly counteracts the direction of rotation. When acting in the axial direction stop the rotation is translated into a contact force to the stop. The contact force of the stop stop on a stop acting in the axial direction is thus greater than on a stop acting in the direction of rotation.

With the arrangement according to the invention, for example, a plurality of dose settings and distributions are possible, with each dose setting, the coupling member is moved a little closer to the stop stop. The distance that the coupling member has to the stop position corresponds to the content contained in the product container.

An example is intended to clarify the application: A product container may contain 300 units of insulin when completely filled. With every single dose adjustment are basically

Values from 1 to 60 or 80 can be set in one or two steps. In a completely filled product container, the coupling member is a certain way of the

Stop position, this path can be divided into the number of units contained in the product container as in this example, 300 units. With each dose setting, the coupling member of the set dose is correspondingly far in the direction

Stop position moves. If, for example, 295 units have been released from the product container, 5 units remain in the product container. Accordingly, the coupling member 5 units away from the stop position. Although with the

Dosageeinstellelement are basically adjustable for each dose setting 60 or 80 units, in this case, the dose setting can only be dosed by 5 units, since then the coupling member gets into the stop with the stop stop, creating a Dose increase is prevented. Thereby, the risk of misuse of the injection device can be reduced.

In preferred embodiments, the coupling member may be coupled to the first member and the second member such that the coupling member is rotatable or rotated relative to at least one, preferably both of the first member and the second member upon movement of the first member relative to the second member becomes. For example, upon rotation of the first member relative to the second member, the coupling member may be rotationally fixed with either the first or the second member and rotate together with the first or second member relative to the other of the first and second members. For this purpose, the coupling member engage in a longitudinal guide, which is preferably formed on the element relative to which the coupling member is rotationally fixed at the dose setting. The coupling member may also in a thread-shaped guide track, in particular a thread, engage, which is formed on the element _"to which the coupling member rotates relatively along with the other member during dose setting.

In the embodiment in which the coupling member rotates relative to the first element and the second element during the rotational movement of the first element relative to the second element, the coupling element can engage in the thread of the first element and in the thread of the second element. As a result, during a rotation, the coupling member is rotated continuously or translated or squat, in particular about the longitudinal axis about which the first and second elements can rotate. The advantage here is that, regardless of whether the dose setting or the first element performs a quarter, a half, a whole or several revolutions relative to the second element, the coupling member always performs a rotational movement relative to the first and the second element. The invention differs here from counting rings, in which, for example, a Einzählring is rotated by a full turn relative to a Zehnerzählring and at the end of the full revolution, the Zehnerzählring entrains by one unit. The part of the one-number ring, which entrains the Zählererzählring, performs the Zählererzählring no relative movement, but to Zählererzählring and only if the Einzählring not take the Zählererzählring. Another advantage of the invention is that the coupling member is rotated during rotation of the first element relative to the second element by a rotation angle which is greater or preferably smaller than the angle of rotation of the first element. This also applies to the rotational angular velocity, ie that upon rotation of the first element relative to the second element, the coupling member is rotated relative to the housing by a rotational angular velocity which is greater or preferably smaller than the rotational angular velocity of the first element. Preferably, the angle of rotation or the angular velocity of the coupling member is greater than that or the second element, since this particularly preferably stands still to the housing at the dose setting.

For example, the angle of rotation or speed of rotation of the coupling member that performs it upon rotation of the first member relative to the second member or housing is greater when the threads or coils have the same sense of rotation and the pitch of the guideway of the first member is greater than the slope of the guideway of the second element. The coupling member performs relative to the second element or the housing a smaller angle of rotation or a slower rotational angular velocity than the first element relative to the second element or the housing, wherein the direction of rotation of the coupling member is opposite to the direction of rotation of the first element relative to the second element, when the Thread or coils have the same direction of rotation and the guideway of the first element has a smaller pitch than the guideway of the second element. The guideways of the first element and the second element can basically have the same direction of rotation and the same gradients.

The coupling member may rotate relative to the second member or housing in the same direction of rotation and at a lesser rotational angle or speed than the first member relative to the second member or housing when the threads or helical guideway of the first member and the second member have an opposite sense of rotation. The pitches of the guideways of the first member and the second member may be equal or the pitch of the guideway of the first member may be greater than that of the second member or vice versa. The pitches of the threads or helical guideways can be very small or very large, wherein at a finely large pitch the guideway is a along the axis of rotation, ie parallel to the axis of rotation extending guide or longitudinal guideway.

The first rotatable element may be connected to a spring, in particular a torsion spring or torsion spring, which stores the energy required for the dose distribution and releases it as needed. Preferably, the spring can be tensioned by the dose setting movement of the dose setting element or of the first element. In principle, the spring can be helical or, preferably, spiral-shaped. The spring may be wound from a wire or preferably from a band-shaped material, in particular spring steel. Such springs are also referred to as clock springs. At least one of dose indicator sleeve, first member, and dose setting member may be rotationally fixedly coupled to one end of the spring at the dose setting, the other end of the spring being advantageously connected to the housing. For the dose distribution, the first element and / or the dose indicator sleeve can be rotationally fixedly coupled to one end of the spring, wherein the dose setting element is decoupled, for example.

The dose indicator sleeve may, for example, have a thread, in particular an internal or external thread, which engages in the housing or in a housing-fixed element in order to perform a screwing movement for the dose display can. For this purpose, the dose display sleeve may have a helical scale arranged on its outer circumference. The dose indicator sleeve can have stops, in particular stops acting in the axial direction or preferably in the circumferential direction, which can strike into corresponding counterstops with, for example, the housing. The dose indicating sleeve may reciprocate between these stops so as to adjust dosages from zero to the desired maximum dose, such as 60 or 80 units, especially if the coupling member is not in the stop position. Thus, a maximum adjustable dose can be limited on the one hand with the stop of the dose display sleeve or with the coupling member, depending on which of the two elements first prevents a dose increase. As is generally preferred, the second rotatable element can be non-rotatably coupled to an output member, in particular a piston rod, wherein the driven member can be screwed in in the discharge direction, in particular for product discharge. For this purpose, the output member may for example have a thread with which it engages in the housing or a housing-fixed element in order to perform the screwing can. For example, the second rotatable element may also be the piston rod. Particularly preferably, the second rotatable element is sleeve-shaped and rotatably coupled to the driven member, wherein the driven member can perform a longitudinal movement relative to the second rotatable member. The second rotatable element may be indirectly or directly coupled to the output member. For example, the second element via a sleeve, in particular a coupling sleeve rotatably or longitudinally slidably coupled to the output member. The second element may be non-rotatably and longitudinally displaceable coupled to the sleeve, which is arranged between the output member and the second element, such as via longitudinal grooves. This has the advantage that, in the event of a product container change, the second element does not need to carry out or execute any axial movement relative to the first element, wherein the output gear and possibly the sleeve surrounding the output element can be axially movable relative to the second element. In particular, the sleeve engaging directly in the output member may be the second element.

In particularly preferred embodiments, at least one of the first element and the second element may comprise a thread-shaped guide track or groove, and the other of the first element and the second element have a thread-shaped or parallel to the longitudinal axis extending guide track or groove, wherein the coupling member, in particular its center of gravity preferred is always located where cross the guideways or grooves in particular in their projection over. It can advantageously be achieved that the annular gap between the first element and the second element is relatively thin. The guideway or grooves may form an enclosure for the coupling member which at least encloses the coupling member so that it remains where the guideways cross each other. The coupling member may be freely movable with a more or less large game in this enclosure. In the projection of the two guideways, the enclosure may, for example parallelogram, in particular rectangular, square or be diamond-shaped. The opposite edges of the parallelogram are formed by one of the guideways. The enclosure ensures that the coupling member remains where the guideways cross each other. Upon rotation of the first member relative to the second member, the skirt, and thus the coupling member therein, moves relative to the first and / or second members. In particular, the coupling member is guided at a dose increase by means of the enclosure to the stop position and guided away at a dose reduction from the stop position. The guideway of the first element forms a first Teileinfassung and the guideway of the second element forms a second Teileinfassung, which together form the enclosure for the coupling member. The coupling member may be substantially entirely disposed within the enclosure, at least the geometric center of gravity or center of gravity of the coupling member is disposed within the enclosure. Particularly advantageous here has a spherical coupling member has been found, with other rotationally symmetrical body, such as a cylindrical, could come into question, especially if one of the two guideways is a longitudinal guide. Also conceivable are other bodies which fit into the enclosure, such as cubes or bodies with a parallelogram-shaped, in particular diamond-shaped, rectangular or square cross-section. Generally preferred is the stop stop on which the coupling member strikes in the stop position adapted to the stop surface of the coupling member to produce as possible a surface pressure. For example, the stop stop for a spherical coupling member may be part of a ball socket, which preferably has the same radius as the spherical coupling member.

In particular, at least one of the guideways or grooves forms a stop acting in the axial or circumferential direction, i. the stop stop for the coupling link.

For example, the end of the guideway of the first member may abut the coupling member in the stop position, the coupling member abutting the end of the guideway of the second member. The coupling member may be clamped between the ends of the guideways of the first and second members. A rotation of the first element relative to the second element for a dose increase is prevented. In principle, an edge of one of the longitudinal guides could also form a stop, with this being particularly preferred in the case of a guideway designed as a longitudinal guide. In preferred embodiments, the coupling member may extend only partially over the circumference of the second rotatable member. Such a coupling member may in principle be one of the abovementioned body provided for the enclosure, wherein it is preferred that the coupling member extends in a segmental manner over the circumference of the second web member. For example, the segment may be part of the circumference of a nut. The two ends facing in the circumferential direction, ie the opposite ends of the segment-shaped coupling member may preferably surround the second rotatable element so far that the connecting straight through the two ends of the circumference of the output member mounted by the second element, such as the piston rod passes or tangent. The fact that the segment does not form a passage for the output member, space can be saved in the annular gap between the first and the second element. The advantage here is that in the annular gap other parts of the injection device can be arranged, whereby the injection device can be made more compact overall. The segment may, like a nut, also have on its end face a stop for the stop stop, which particularly preferably points or acts in the direction of rotation.

In particular in the annular gap can be arranged relative to the coupling member opposite a support member relative to the circumference of the second element. The support member may be inserted as a separate part in the annular gap or formed on one of the first element, second element and coupling member. For example, the support member may be formed projectingly on the second element in the annular gap, wherein the coupling member is longitudinally guided on the second element. The support member may hereby be supported on the inner circumference of the first element or slide along it. The support member may alternatively be formed on the first element and protrude into the annular gap, wherein the coupling member is guided longitudinally on the first element. The support member may in this case be supported on the outer circumference of the second element, in particular slide along it. By a support member can be advantageously achieved that in improper use, for example when the user with force on the dose setting rotates the first or the second element can not be deflected from their concentric arrangements, for example, if the coupling member is strongly pressed against the stop stop. Alternatively or in addition to the support member, the stop of the coupling member or the stop stop or both may have a corresponding shape, which prevents the first and / or second element is deflected from its axis of rotation.

In preferred embodiments, the coupling member may be positively, positively and / or materially connected, in particular with at least one predetermined breaking point with a base element, wherein this compound is releasable in the first rotation of the first element relative to the second element. For example, the base member may be disposed in the annular gap between the first and second members. Also possible is an embodiment in which the base member forms the support member. Base element and coupling member may be integrally formed in an initial position, in particular prior to a first use of the injection device, in particular by an injection molding process. There may be provided webs for forming predetermined breaking points, which break when the first element moves relative to the second element, e.g. the coupling member is axially and / or rotationally moved relative to the base member. The base element advantageously serves as an assembly aid for the coupling element, in particular the segment-shaped coupling element.

In preferred embodiments, the coupling member may extend at least partially, in particular completely, around the circumference of the second rotatable member, e.g. to form a mother. Preferably, two thread-shaped guideways are provided in this embodiment. For this embodiment, it is preferred that the pitch of one of the two thread-shaped guideways in which the coupling member engages is greater than the pitch of the other of the two thread-shaped guideways. According to the herein mentioned examples of the crossing guideways for the coupling member, an equal or opposite sense of rotation or an over- or reduction are generated, wherein the movement of the coupling member is continuous.

In particular, the rotation of the coupling member relative to the first element or to the second element may be less than one full revolution when the coupling member is moved from the position in which it is farthest from the stop position to the stop position, and for this purpose at least one of Guides have a very large thread pitch. As a result, an advantageous friction situation in the Injection device achieved. The coupling member is the furthest away from the stop position, especially with a full product container.

In certain embodiments, it may be advantageous if the guideways have a width which widens or tapers to the stop position, whereby a play for the coupling member can be increased or reduced in the movement to the stop position. In addition, there are advantages in the production of the second element, e.g. during the removal from an injection mold.

The invention has been described with reference to several Ausffihrungsfoπnen. In the following, preferred embodiments of the invention will be described with reference to figures. The features disclosed in this case each individually and in combination, the subject of the invention advantageously continue. Show it:

Figure 1 is a cross-sectional view of a proximal part of a

Inj eküonsvorrichtung,

Figure 2 is a perspective view of a driven member with flange and

Spring member

Figure 3 is a perspective view of a modified coupling sleeve for the device of Figure 1, Figure 4 is a perspective view of a further modification for the

Device of Figure 1,

Figure 5 is a cross-sectional view with the modification of Figure 4, Figures 6 and 7 are perspective views of a further modification for the

Device of Figure 1,

Figure 8 is a cross-sectional view showing the modification of Figures 6 and 7, Figures 9 and 10 are perspective views of a further modification of the

Device of Figure 1,

Figure 11 is a cross-sectional view with the modification of Figures 9 and

10, FIG. 12 shows a perspective view of a development of the modification from FIGS. 9 to 11, Figure 13 is a perspective view of a further modification for the

Device of Figure 1, Figure 14 is a perspective view of a further modification for the

Device of Figure 1 and Figure 15 is a cross-sectional view of a multi-part coupling member.

The injection device shown in Figure 1 comprises a drive unit, which is preferably reusable, and a product container 27 connected thereto, which is in a sleeve-shaped, e.g. accommodated reusable product container receptacle 16 and with the help of the Produktbehältaisaufnahme 16 can be attached to the drive unit. The product container 27 can be removed after its emptying of the Injeklionsvorrichtung, disposed of and replaced with a new one. The housing 12 is formed in several parts because of the ease of manufacture and assembly with associated or inserted elements 12a, 12b, wherein the housing could in principle be formed in one piece. The product container 16 is fastened to the drive unit by means of a bayonet closure, which is formed by the housing 12, the product container receptacle 16 and the sleeve 50. The product receptacle receptacle 16 is covered by a cap 31, which is plugged into the housing 12, removable for use of the injection device and then re-attachable.

For attaching the product container 27 to the drive unit, a new product container 27 is inserted through the proximal end into the product container receptacle 16. Subsequently, the Produktbehältnisaufnahme 16 with an axial movement or a combined rotational and axial movement torque-tight to the sleeve 50 infected.

In the sleeve 50, which may also be referred to as a bayonet sleeve, is a guide sleeve

26 recorded. The guide sleeve 26 is rotationally fixed to the housing 12 and axially movable and connected to the bayonet sleeve 50 rotatably and axially fixed. This causes, during the movement of the bayonet sleeve 50 from the unlocked to the locked position and conversely, the guide sleeve 26 performs a longitudinally guided movement relative to the housing 12.

As can be seen in Figure 1, a threaded insert 6 is rotatably and axially fixed to the guide sleeve 26 is connected, in particular latched. Threaded insert 6 and guide sleeve

26 may be referred to as engaging member 6, 26. The threaded insert 6 has a

Internal thread 6a, in which the external thread 2a of a driven member 2, in this

Example can also be referred to as piston rod, is guided, so that if that

Output member 2 is rotated, this is guided by the internal thread 6a of the threaded insert 6, depending on the direction of rotation either in the proximal direction or in the distal, i. opposite direction screws.

The output member 2 carries on its outside a thread 2a soft from two opposite to the circumference, extending in the axial direction grooves 2b is interrupted. A coupling sleeve 5, which is part of a transmission element 7, K2, 5, has at its distal end two opposing radially inwardly directed Abragungen 5a, 5b, which project into the grooves 2b of the output member 2. The coupling sleeve 5 is rotatably and axially fixedly connected to the engaging member 6, 26. Thus, the output member 2 is secured against rotation relative to the coupling sleeve 5 and can be moved axially relative to the coupling sleeve 5, when it is rotated relative to the engaging member 2, 26. Except during an exchange of the product container 27, the coupling sleeve 5 is not axially displaceable.

A provided at the proximal end of the injection device drive shaft 7, which is part of the transmission element 7, K2, 5, has radially inwardly projecting teeth 7a, which form a coupling element of the clutch K2. By the actuations, i. Pressing an actuating element 15 in the distal direction, the drive shaft 7 and thereby also the teeth 7 a are displaced in the distal direction, whereby the teeth 7 a engage in the proximal end of the coupling sleeve 5 and form a torque-resistant, in particular positive connection.

A spring element or a drive spring 3, which may be in the form of a spiral spring or clock spring, is connected at one end to the housing 12 via a spring sleeve 8 connected on the outside of the spring element 3. The spring sleeve 8 is secured against rotation relative to the housing 12 and axially displaceable. At the other end, the drive spring 3 is connected to the drive shaft 7. As a result, energy stored in the spring element 3 can be output as a rotational movement of the drive shaft 7 relative to the housing 12. For a product distribution, the energy of the spring element 3 is delivered via the transmission element 5, K2, 7 in the form of a rotational movement to the driven member, so that this screwed relative to the engaging member 6, 26 in the distal direction, ie in the dispensing direction and the piston 28 shifts which pours the product from the product container 27.

To set a dose of product to be administered, a user can rotate the metering element 9, designed as a metering button, which is axially fixed relative to the housing 12. The metering element 9 is coupled via the coupling K3 with a coupling member 10 secured against rotation. The coupling K3 is formed by webs or grooves or teeth of the Dosierknopfes 9, which cooperate positively with webs or grooves or teeth of the clutch disc 10 to form a detachable by displacement of the coupling member 10 in the distal direction coupling. The coupling member 10 can be moved by actuation of the actuating element 15 and thus released. In an unactuated state, the clutches K3 are engaged in a clutched state and the clutch K2 is held in a disengaged state by means of a spring element 19 which urges the drive shaft 7 in the proximal direction. During the dose setting process, the clutch K3 is engaged, i. a rotational movement of the Dosierknopfes 9 is transmitted to the coupling member 10. The coupling member 10 is connected to the drive shaft 7 axially and rotationally fixed and could also be integrally formed with the drive shaft 7. The rotational movement of the dosing member 9 is not transmitted to the coupling sleeve 5 due to the disengaged clutch K2.

By rotation of the drive shaft 7 connected to the drive shaft 7 drive spring 3 is tensioned. In order to prevent that the dosing knob 9 is rotated back again by the tensioned during the adjustment operation of the dosing knob 9, a ratchet 11 or a ratchet mechanism, which may have a ratchet spring I Ia, for example, for clamping holding elements, between the housing 12 of the injection device whose Components may be, for example, a mechanism holder 12 a and a mechanism holder 12 b, and the dosing 9 provided. The ratchet mechanism can be designed so that only the rotation in one direction, in particular only a tensioning of the drive spring 3 is possible. However, it is preferred that the ratchet mechanism is designed so that the rotation in both directions, in particular a tensioning and relaxing the drive spring 3 is possible. Rotatable in both directions can increase and decrease product dose when adjusting the product dose. The currently set product dose can be read via the window 12d of a display drum 4.

The rotational movement of the drive shaft 7 is also transmitted to the threaded sleeve 13, which is rotatably and axially fixed to the drive shaft 7 and could also be integrally formed therewith. The threaded sleeve 13 carries on its outer periphery 13a at least one groove into which at least one web 4a of the display drum 4 engages, so that a rotational movement of the threaded sleeve 13 is transmitted to the display drum 4 by the rotation-proof coupling, wherein an axial relative movement between the display drum 4 and Thread sleeve 13 is possible. The display drum 4 has on its outer side a thread 4b, which engages in an internal thread 12c of the housing part 12b, so that the display drum 4 is displaced by a rotational movement in the axial direction relative to the housing 12, preferably in the distal direction. Preferably, the indicator drum 4 moves during an adjustment or Aufdosiervorganges by rotation of the Dosierknopfes 9 in the distal direction of the injection device (in Fig. 1 to the left). On the outside of the display drum 4 may be provided a mark, such as a label, a dose indicator or a scale, which is read through an opening or window 12d in the housing 12b of the injection device, wherein the marking of the display drum 4 relative to the window 12d shifts. The display drum 4 has at its distal end a unidirectional rotational stop which, at maximum dose, comes into abutment with a counter-stop correspondingly formed on the housing part 12a. The counter-stop is formed by a front end of an annular gap of the housing part 12a. A stop acting in the circumferential direction has the advantage over an axial stop that lower forces act on the stop. The display drum 4 also has at its proximal end another in Circumferentially acting rotation stop, which gets into a stop with a correspondingly formed on the housing 12b counter-stop at minimal dose. The counter-stop is formed by the proximal end of the thread 12c.

After setting the dose and mounting the drive spring 3 by turning the Dosierknopfes 9 of the adjustment is completed, it being preferred that the tensioning of the spring 3 takes place during the dosing. For dose correction, the dosing knob 9 can be easily rotated in the opposite direction to reduce a possibly set too large dose again.

The ratchet 1 1 may be formed as described in Figures 14 and 15 of the patent application PCT / CH2007 / 000243, the relevant teaching is included in the patent application.

During a dispensing operation, which is triggered by pressing the push button 15, the display drum 4 is again rotated in the opposite direction and shifts by the threaded engagement with the internal thread 12c of the injection device back in the proximal direction (in Fig. 1 to the right). In this case, it can also come to a stop acting in the circumferential direction of the display drum 4 to the housing 12a, 12b of the injection device and in particular to the housing part 12b. This process, in the case of an unrestrained dispensing movement, in which the threaded rod 2 is moved without counterforce in the distal direction, e.g. if no product container is inserted, lead to a heavy load and in extreme cases to a deformation or even damage to the display drum 4 or the counterpart 12b. It is therefore an acting on the drive movement braking device 17, 18 is provided.

The clutch K1, which is formed from the coupling member designed as a locking sleeve 14 and the coupling sleeve 5, serves to couple the coupling sleeve 5 in certain switching states in a rotationally fixed manner to the housing 12 or to decouple it for rotation relative to the housing 12. The clutch K1 is preferably decoupled when the product container 27 is replaced, in order to be able to push the output member 2 back in the proximal direction or screwed back, and with a product discharge to the product To be able to screw output member 2 in the distal direction. The clutch K1 is preferably engaged when the product container is attached to the drive unit and the actuator 15 is unaccounted for. The clutch Kl is formed by teeth on the outside of the coupling sleeve 5, which engage in teeth on the inside of the locking sleeve 14. As a result, the coupling sleeve 5 is secured against rotation relative to the locking sleeve 14. The locking sleeve 14 is secured against rotation and axially displaceable in the injection device, in particular mounted relative to the housing 12 and the coupling sleeve 5.

During a dispensing operation, the threaded sleeve 13 is displaced by actuation of the actuating element 15 in the distal direction. In this case, the threaded sleeve 13 presses on the bearing 29, which is formed in this example as a ball bearing, but may also be designed as a plain slide bearing, the bearing 29 presses on the locking sleeve 14, this thus shifts for a dispensing in the distal direction and during a Holding the dispensing process in the distal position. The coupling member 14 is thus distal to the projections of the coupling sleeve 5 for the clutch Kl. Thus, the clutch Kl is disengaged for the duration of the dispensing operation.

Upon actuation of the actuator 15, the clutches Kl, K2 and K3 behave as follows: By pressing the seated on the coupling member 10 and / or drive shaft 7 push button 15, the coupling member 10 are moved together with the push button 15 and the drive shaft 7 in the distal direction. As a result, the clutch K2 engages, so that the drive shaft 7 is secured against rotation with the coupling sleeve 5.

Subsequently, the clutch Cl couples by displacement of the locking sleeve 14, soft on the connected to the drive shaft 7 threaded sleeve 13 via the axially displaceable bearing

29 expresses, off. The clutches K1 and K2 can alternatively also be reversed

Order to be switched.

After engaging K2 and disengaging Kl, the clutch K3 also disengages by moving the coupling member 10 relative to the dosing knob 9. The

Coupling member 10 which is connected to the drive shaft 7, can after the

Disconnect the clutch K3 rotate relative to the housing 12. The in the drive spring 3 energy or force stored during the metering may be transferred to the drive shaft 7. Thus, a torque is applied to the drive shaft 7, which is transmitted by means of the engaged clutch K2 on the coupling sleeve 5, which rotates together with the drive shaft 7 and transmits this rotational movement to the rotationally fixed to the coupling sleeve 5 output member 2. The output member 2 designed as a threaded rod in this example converts the rotational movement due to the threaded engagement 2a, 6a with the engagement member 6, 26 into an axial movement in the distal direction, so that the flange 1 provided at the distal end of the threaded rod 2, which is also the output member can be attributed, is moved in the distal direction of the injection device.

Since the threaded sleeve 13 rotates in the opposite direction as when metering in the product distribution, the display drum 4 also rotates in the opposite direction as in the metering.

Normally, i. in the case where the preset product dose is completely released, the dispensing operation, and in particular the displacement of the driven member 2 in the distal direction, continues until the abovementioned circumferentially acting stop of the indicating drum 4 strikes. This is preferably done when the value readable by window 12d has dropped to zero.

In the case where the user of the device releases the actuation element 15 during product dispensing, the clutches couple in reverse order as they have disengaged upon actuation. The product distribution is interrupted, whereby through the window 12d the value can be read, which would still have to be distributed, that the pre-set dose would be completely distributed. The product distribution can be continued by the actuating element 15 is pressed again, the release can be stopped by releasing the actuator 15 again or can be maintained until the product is discharged completely. In the event that there is less product in the product container than the maximum dose is indicated on the display drum, the injection device shown in this example has additional means for limiting the last maximum dose that can be set to prevent a larger product dose from being adjusted when product is in the product container. For this purpose, a coupling member 30 is provided, which can also be referred to as a runner. The rotor 30 surrounds the coupling sleeve 5 at least partially and is in such an engagement with the coupling sleeve 5 that the rotor 30 is rotatable relative to the coupling sleeve 5 and axially displaceable. The rotor 30 also engages with a thread formed on its outer circumference into an internal thread of the threaded sleeve 13. This arrangement causes an axial movement of the rotor 30 takes place at a relative rotation between the threaded sleeve 13 and the coupling sleeve 5, wherein at no relative rotation of the rotor 30 performs no axial movement. When setting a product dose, the threaded sleeve 13 is rotated relative to the coupling sleeve 5, so that the rotor 30 moves in the proximal direction. When dumping, however, there is no relative movement between the coupling sleeve 5 and threaded sleeve 13 due to the clutch engagement of the clutch K2 instead. The runner will not move. After repeated dosing and Produktausschutten the rotor 30 in an axial stop with the drive shaft 7, whereby a further dose increase is no longer possible, even then no longer if the display 4, 12d actually allow more.

The user can replace the product container 27 with a new one. For this purpose, he removes the product container holder 16 by rotation relative to the housing 12 of the drive unit. In the movement from the fixed position to the unsecured position of the product container 27, in particular when unlocking the bayonet closure, the engaging member 6, 26 is displaced together with the driven member 2 and the coupling sleeve 5 relative to the housing 12 and the coupling member 14 in the distal direction, whereby the clutch Kl is released. The provided for the clutch Kl radially outward protrusions of the coupling sleeve 5 are now distal of the coupling member 14. On the output member 2, in particular its flange can now be applied a relatively small force acting in the proximal direction, whereby the output member 2 in the drive unit screws. The thread of the output member 2 is not self-locking. When screwing back the driven shoe 2, the coupling sleeve 5 is rotated relative to the threaded sleeve 13 and indeed opposite as in the product distribution, whereby the rotor 30 is again axially displaced in the distal direction. The screwing back can be done at least over part of the total path against the force of a spring member, for example, trying to move the output member in the distal direction. The spring member can eg act or be arranged between the output member 2 and the drive shaft 7. Further advantageous spring members are described in particular to Figure 2 below. It is generally preferred that the force of such a spring member is less than the force required for interaction via the piston with the product of the output member 2.

Further, upon removal of the product container 27, the holding member 25 "serving to fix the product container 27 in the product container holder 16 is displaced by the spring 19 in the distal direction until it comes into abutment with the engaging member 6, 26. This stop prevents the spring 19 from being able to completely relax when the product container 27 is removed. This is advantageous because the spring 19 should apply sufficient force even with a remote product container 27 to hold the clutch K3 in a clutch engagement, whereby the actuator 15 remains in its most proximal position.

According to another aspect, a sprung flange can be realized, such as e.g. shown in Fig. 2.

After a change of the preferably designed as a vial or cartridge product container 27, the user, as described in the manual, called for so-called venting or priming. This is necessary because, on the one hand, there is air in the product container 27 and, on the other hand, the driven member 2 has previously been pushed completely into the drive unit and due to the different filling level of the

Product container 27 some play between the piston 28 and the flange 1 has arisen. FIG. 2 shows an output member 2 with a flange 1 attached to its front or distal end, which is immovably connected to the threaded rod. Between the flange 1 and the threaded insert 6 shown in Figure 2, a spring member 38 is provided, which can be realized for example by obliquely projecting spring arms 38a. These spring arms 38a may be attached to the flange 1 and / or on the threaded insert 6. Likewise, an elastomer on the flange 1 and / or on the threaded insert 6 could be molded. After inserting a new product container 27, there may be a play between the flange 1 and the piston 28, which is particularly due to different levels of full product containers 27, which have a certain tolerance.

After the insertion of the threaded rod 2 connected to the flange 1, the flange 1 is according to the embodiment shown in Figure 1 directly to the threaded insert 6 at.

According to the embodiment shown in Figure 2, however, the flange 1 is pushed away by the at least one spring member 38 from the threaded insert 6 by a predetermined distance in the distal direction. This makes it possible that always comes to rest in a deployed product container 27 or upon insertion of the Produktbehällnisses 27 of the flange 1 on the proximal side of the piston 28 even when the piston 28 due to various product containers by manufacturing tolerances to different extents in the Produktbehältm ^'s 27 is inserted.

Conventional measures to eliminate the play between flange 1 and piston 28 are therefore no longer mandatory and can e.g. even omitted.

As can be seen from FIG. 1, the injection device, in particular the drive unit, has a brake 17, 18 which brakes a rotating part, in this example the transmission element 7, K2, 5 or / and the drive movement. In conventional injection devices there is the risk of overloading or even damage to the components of the injection device in case of misuse, for example, when no product container is inserted and yet actuation of the Injektinosvorrichtung is made. In an inserted product container 27 is by the viscosity the product during product distribution, a damping of the forces and movements made. In the case of a missing product container, such an attenuator is missing. Remedy the brake 17, 18, which avoids overloading.

The modified coupling sleeve 5 of Figure 3, which serves as the coupling element 5 of Figure 1 as a second element is basically constructed as the coupling sleeve of Figure 1. In particular, the coupling sleeve 5 has a parallel to the axis of rotation about which the coupling sleeve rotatable is, extending guideway 5d, in particular a longitudinal groove. In the guideway engages configured in this example as a ball coupling member 30 a. The guide track 5d is rounded in cross section, in particular with a radius which corresponds approximately to the spherical radius. Through the guide track 5d, the ball 30 is guided parallel to the longitudinal axis of the coupling sleeve 5. Instead of a ball, another rotational body could also be guided by the guide track 5d, for example a cylinder. The ball 5d further engages the threaded track 13b of the first-member threaded sleeve 13 (e.g., Figure 1 or Figure 5). The guideway 13b may also be rounded in cross-section as the guideway 5d.

The modification shown in Figures 4 and 5 corresponds in principle to the embodiment of Figure 3, wherein the guide track 100c for the ball 30 is not formed by the coupling sleeve 5 but by an intermediate sleeve 100, namely at its outer periphery. The intermediate sleeve 100 is rotatably connected and axially displaceable with and relative to the coupling sleeve 5, as in this example with longitudinal guides which are formed on the outer circumference of the coupling sleeve 5 and engage in the projections formed on the inner periphery of the intermediate sleeve 100.

The advantage of the intermediate sleeve 100 in all modifications shown herein is that it can be placed on the one hand on the coupling sleeve 5 of Figure 1 and on the other hand when exchanging the product container, the intermediate sleeve 100 does not need to perform longitudinal movement, since the coupling sleeve 5 is longitudinally movable relative to the intermediate sleeve 100 ,

In the embodiments of Figures 3 to 5, the threaded sleeve 13 is relative to the coupling sleeve 5, the coupling member 30 and possibly the Intermediate sleeve 100 is rotated, wherein the coupling member 30 is rotatable relative to the coupling sleeve 5 or the intermediate sleeve 100 and performs a longitudinal movement along the guide track 5d or 100c. "Rotationally" refers to the rotation of the ball 30 relative to the longitudinal axis of the coupling sleeve 5 or the intermediate sleeve 100 and not to the rotatability of the ball 30 about its center of sphere. The ball 30 comes in its stop position into abutment with the end of the guide track 13b and the edge of the longitudinal guide 5d or 100c, whereby a dose increase is prevented.

The modification shown in FIGS. 6 to 8 has an intermediate sleeve 100 which, like the intermediate sleeve 100 from FIGS. 4 and 5, is connected to the coupling sleeve 5 and which, instead of a guideway 100c extending parallel to the longitudinal axis, extends along a thread or helix having the longitudinal axis extending guideway 100c. The thread or helical guide track 100c has a smaller pitch than the thread or helical guide track 13b of the threaded sleeve 13. The guideway 100c has one of the guideway 13b opposite direction of rotation. As can be seen in particular from FIG. 8, the ball 30 is arranged where the guide tracks 13b and 100c cross each other and form a border for the ball 30. At the point where the guideways 13b and 100c cross each other, they form a diamond-shaped enclosure in the projection, in which the ball is guided with a game.

Upon rotation of the threaded sleeve 13 relative to the intermediate sleeve 100, the ball 30 is continuously rotated with the threaded sleeve 13, but at a lower angular velocity than the threaded sleeve 13 rotates. Due to the squat movement of the ball 30, the mechanism saves space.

At each dose increase, the ball 30, which is in a full product container in the position shown in Figure 6, is moved by a dose corresponding to the stop stop 100a formed by the end of the thread 100c. In Figure 7, the ball is in its stop position, ie in abutment with the stop stop 100a. The end of the guide track 13c is in the position of the ball shown in Figure 7 also in a stop with the ball 30, namely the Stop 100a lying opposite, wherein in Figure 7, the threaded sleeve 13 has been omitted for purposes of illustration.

FIGS. 9 to 11 show a modification for the device from FIG. 1 with a coupling element designed as a segment 30, wherein the segment 30 engages with projections 30c in longitudinal guides 5c of the coupling sleeve 5. The segment 30 is relative to

Coupling sleeve 5 rotationally fixed and longitudinally movable. The segment 30 has at its

Outer periphery on a threaded portion 30b, which engages in the thread 13b. The

Segment 30 is moved in the direction of stop position at a dose increase, which is shown in Figure 9 and in which a stop 7b into engagement with the stopper 30a, whereby rotation of the drive shaft 7 and the associated threaded sleeve 13 relative to the

Coupling sleeve 5 and the segment 30 is prevented.

The stops 7b, 30a have arranged transversely to the longitudinal direction abutment surfaces, by the shape of the segment 30 is attracted to the drive shaft 7. Due to the shape of the correspondingly inclined abutment surfaces, the rotational stop acting in the circumferential direction is very stable.

The segment has two ends in the circumferential direction, which are each connected in FIGS. 9 and 10 with a connecting straight line drawn as a dashed-dotted line. However, this imaginary connecting straight line does not intersect the coupling sleeve 5 with the piston rod 2 accommodated in the coupling sleeve 5, but touches or passes through it. It is not filled the entire annular gap between the threaded sleeve 13 and coupling sleeve 5, whereby the segment 30 is space-saving.

The segment 30 shown in FIG. 12 is an advantageous further development of the segment from FIGS. 9 to 11 and, in principle, also constructed in this way. However, the segment 30 is formed with a plurality of predetermined breaking points 300a in a material-locking manner on a base element 300. When mounting the one-piece, formed from the segment 30 and the base member 300 part mounted on the coupling sleeve 5, wherein the base member 300 as the segment 30 is secured against rotation about the longitudinal guides 5c. However, in contrast to the segment 30, the base element is axially fixed relative to the coupling sleeve 5. At a dose setting, in particular dose increase, the segment 30 is axially displaced in the direction stop position relative to the base member 300, whereby the predetermined breaking points 300a break. The base member 300 advantageously allows easy assembly of the segment 30. The base member 300 forms a sleeve portion, part of which is the segment 30. The remaining part of the sleeve portion on the base member 300 may form a support member which supports the coupling sleeve 5 against movement transverse to the longitudinal axis.

Figure 13 shows a coupling member in the form of a nut 30 which completely surrounds the coupling sleeve 5, i. forms a passage. For example, instead of the nut 30, a segment could be provided since, apart from the fact that it forms a closed ring, the nut is constructed like the segment of FIGS. 9 to 11. The coupling sleeve of Figure 13, however, has a thread-shaped guide track 5c, whose direction of rotation is opposite to that of the threaded portion 13 and which has a greater pitch than the threaded portion 30b, which engages in the thread 13b of the threaded sleeve 13. Due to the arrangement, the nut 30 is continuously rotated in the dose setting with the threaded sleeve, wherein the nut 30 performs a lower rotational angular velocity than the threaded nut 13. By this reduction, the mechanism saves space.

The threaded sleeve 5 from FIG. 14 has a guideway 5c that widens in the proximal direction and can be used, for example, with a nut-shaped coupling element, such as that shown in FIG. 13. The widening guide track 5c facilitates removal of the coupling sleeve 5 from an injection molding tool. The particular groove-shaped guide track 5c is delimited on both sides by a respective flank, wherein at least one flank extends helically over the circumference. The other flank may also be arranged approximately parallel to the longitudinal axis of the coupling sleeve 5. As a result, advantages of the modifications of Figures 13 and 14 are combined, so that the coupling sleeve 5 is easily demoldable and the stop nut 30, which rests at a dose increase at the helically extending edge performs a continuous and squat rotational movement when the coupling sleeve 5 is rotated becomes. In the embodiment of FIG. 14, in a dose correction or at least a portion of the dose correction, the stop nut 30 does not need to move in the reverse sequence of movements as in metering because the distance between the helical flank and the flank extending parallel to the longitudinal axis of the coupling sleeve increases with increasing travel enlarged in the proximal direction. As a result, an increasing gap between at least one of the flanks and the part of the coupling member 30 which engages in the guide track 5c arises as the path in the proximal direction increases.

FIG. 15 shows a multipart coupling element, in particular a two-part coupling element, which has a guide part 30m and a stop part 30n that is rotatable relative to it and axially fixed. The

Guide member is longitudinally guided on the second element and engages in the thread of the first

Element. The stop member 30n has a circumferentially acting stopper 30a. Between guide member 30m and stopper member 3On is disposed a ratchet 301 which generates tactile and audible KJicks when the guide member 30m is twisted relative to the stop member 30n, namely, when the stopper 30a is in a corresponding counter-abutment, e.g. 9 is denoted by the reference numeral 7b. This will be the

Reaching the stop position the user at the last in the product container contained

Cans announced. Guide member 30m and stop member 30n may optionally be with a spring

(not shown) rotationally biased against each other.

Claims

claims

An injection device comprising: a) a dose setting member (9; 10; 7; 4) and a first member (13) coupled thereto rotatable at a dose setting relative to another second member (2; 5; 100) a dose distribution relative to the second element (2; 5; 100) is rotationally fixed, wherein the first element (13) and the second element (2; 5; 100) are coupled via a coupling member (30), and b) a stop stop ( 7b, 100a), wherein at a dose setting the coupling member

(30) performs a movement towards a stop position, wherein the coupling member (30) in the stop position prevents the setting of a dose.

2. Injection device, wherein the coupling member (30) is a ball, a ring, a stop nut or a segment.

3. Injection device according to one of the preceding claims, wherein the coupling member (30) in a guideway, in particular internal thread of the first element (13) and in a guideway, in particular external thread of the second element (2; 5; 100) engages.

4. Injection device according to one of the preceding claims, wherein the coupling member (30) is coupled to the first element (13) and the second element (2; 5; 100) in such a way that the coupling element (30) is moved during a movement of the first element (13). 13) relative to the second member (2; 5; 100) relative to at least one, preferably both of the first member (13) and the second member (2; 5; 100) is rotatable or rotated.

5. Injection device according to one of the preceding claims, wherein the coupling member (30) is rotated during a rotation of the first element (13) relative to the second element (2; 5; 100) by a rotation angle which is greater or preferably smaller than that Angle of rotation of the first element (13).

6. An injection device according to any one of claims 1, 2 and 4, wherein the coupling member (30) is formed in a longitudinal guide (5d; 100c) formed on a first element (13) and second element (2; 5; 100). and engaging in a thread-shaped guideway (5c; 100c; 13b) formed on the other of first member (13) and second member (2; 25; 100).

7. Injection device according to one of the preceding claims, wherein the first rotatable element (13) rotatably coupled to a dose display sleeve (4) and / or a torsion spring (3).

8. Inj ektions device according to one of the preceding claims, wherein the second rotatable element (5; 100) rotationally fixed to a driven member (2), in particular a piston rod is coupled, wherein the driven member (2) in particular for a product distribution in the discharge direction can be screwed.

9. Injection device according to one of the preceding claims, wherein the first rotatable element (13) and / or the second rotatable element (2; 5; 100) are sleeve-shaped.

10. Injection device according to one of the preceding claims, wherein at least one of the first element (13) and the second element (2; 5; 100) has a thread-shaped guideway (13b; 100c) and the other of the first element (13) and the second element (13). 2, 5, 100) has a thread-shaped or parallel to the longitudinal axis extending guide track (5d, 13e, 100c), wherein the coupling member (30), in particular its center of gravity is located where the guide tracks (5d;

13b; 100c).

11. Injection device according to the preceding claim, wherein the guideways (5d; 13b; 100c) form an enclosure for the coupling member (30) which at least encloses the coupling member (30) so that it remains where the guideways (30) cross.

12. Injection device according to one of the two preceding claims, wherein at least one of the guide tracks (5d; 13b; 100c) is concave and / or rounded in cross-section and / or approximately circular.

13. Injection device according to one of the three preceding claims, wherein at least one of the guide tracks (5d; 13b; 100c) forms an axially or circumferentially acting stop (100a) for the coupling member (30).

14. Injection device according to one of the preceding claims, wherein the coupling member (30) extends only partially, in particular segmentally over the circumference of the second rotatable element (5; 100), wherein the connecting line of the circumferentially facing ends of the coupling member (30) the circumference of the driven element (2), in particular of the piston rod (2), mounted by the second element (5; 100), passes or is tangent.

15. Injection device according to one of the preceding claims, wherein relative to the circumference of the second element (2; 5; 100) the coupling member (30) opposite a support member (300) is arranged.

16. Injection device according to one of the preceding claims, wherein the coupling member (30) non-positively, positively and / or cohesively, in particular with at least one predetermined breaking point (300 a) with a base member (300) is connected, wherein the compound in the first rotation of the first element (13) relative to the second element (2; 5; 100) is releasable.

17. Injection device according to one of the preceding claims, wherein the coupling member (30) extends at least partially, in particular completely over the circumference of the second rotatable element (2; 5; 100), the pitch of one of the two thread-shaped guideways (13b; 100c) , in which the coupling member (30) engages, is greater than the pitch of the other of the two thread-shaped guideways

(13b; 100c).

18. Injeklionsvorrichtung according to any one of the preceding claims, wherein the rotation of the coupling member (30) relative to the first element (13) or to the second element (2; 5; 100) is smaller than a full revolution when the coupling member (30). is moved from the position in which it is furthest from the stop position to the stop position.